23 |
|
* The first step is opening one or more rendering processes |
24 |
|
* with a call to ray_pinit(oct, nproc). Before calling fork(), |
25 |
|
* ray_pinit() loads the octree and data structures into the |
26 |
< |
* caller's memory. This permits all sorts of queries that |
27 |
< |
* wouldn't be possible otherwise, without causing any real |
26 |
> |
* caller's memory, and ray_popen() synchronizes the ambient |
27 |
> |
* file, if any. Shared memory permits all sorts of queries |
28 |
> |
* that wouldn't be possible otherwise, without causing any real |
29 |
|
* memory overhead, since all the static data are shared |
30 |
|
* between processes. Rays are then traced using a simple |
31 |
|
* queuing mechanism, explained below. |
32 |
|
* |
33 |
< |
* The ray queue holds as many rays as there are rendering |
34 |
< |
* processes. Rays are queued and returned by a single |
33 |
> |
* The ray queue buffers RAYQLEN rays before sending to |
34 |
> |
* children, each of which may internally buffer RAYQLEN rays. |
35 |
> |
* |
36 |
> |
* Rays are queued and returned by a single |
37 |
|
* ray_pqueue() call. A ray_pqueue() return |
38 |
|
* value of 0 indicates that no rays are ready |
39 |
|
* and the queue is not yet full. A return value of 1 |
46 |
|
* myRay.rorg = ( ray origin point ) |
47 |
|
* myRay.rdir = ( normalized ray direction ) |
48 |
|
* myRay.rmax = ( maximum length, or zero for no limit ) |
49 |
< |
* rayorigin(&myRay, NULL, PRIMARY, 1.0); |
49 |
> |
* rayorigin(&myRay, PRIMARY, NULL, NULL); |
50 |
|
* myRay.rno = ( my personal ray identifier ) |
51 |
|
* if (ray_pqueue(&myRay) == 1) |
52 |
|
* { do something with results } |
54 |
|
* Note the differences between this and the simpler ray_trace() |
55 |
|
* call. In particular, the call may or may not return a value |
56 |
|
* in the passed ray structure. Also, you need to call rayorigin() |
57 |
< |
* yourself, which is normally for you by ray_trace(). The |
58 |
< |
* great thing is that ray_pqueue() will trace rays faster in |
57 |
> |
* yourself, which is normally called for you by ray_trace(). The |
58 |
> |
* benefit is that ray_pqueue() will trace rays faster in |
59 |
|
* proportion to the number of CPUs you have available on your |
60 |
|
* system. If the ray queue is full before the call, ray_pqueue() |
61 |
|
* will block until a result is ready so it can queue this one. |
84 |
|
* ray_psend(&myRay); |
85 |
|
* } |
86 |
|
* |
87 |
< |
* The ray_presult() and/or ray_pqueue() functions may then be |
88 |
< |
* called to read back the results. |
87 |
> |
* Note that it is a fatal error to call ra_psend() when |
88 |
> |
* ray_pnidle is zero. The ray_presult() and/or ray_pqueue() |
89 |
> |
* functions may be called subsequently to read back the results. |
90 |
|
* |
91 |
|
* When you are done, you may call ray_pdone(1) to close |
92 |
|
* all child processes and clean up memory used by Radiance. |
103 |
|
* If you just want to reap children so that you can alter the |
104 |
|
* rendering parameters without reloading the scene, use the |
105 |
|
* ray_pclose(0) and ray_popen(nproc) calls to close |
106 |
< |
* then restart the child processes. |
106 |
> |
* then restart the child processes after the changes are made. |
107 |
|
* |
108 |
|
* Note: These routines are written to coordinate with the |
109 |
|
* definitions in raycalls.c, and in fact depend on them. |
110 |
|
* If you want to trace a ray and get a result synchronously, |
111 |
|
* use the ray_trace() call to compute it in the parent process. |
112 |
+ |
* This will not interfere with any subprocess calculations, |
113 |
+ |
* but beware that a fatal error may end with a call to quit(). |
114 |
|
* |
115 |
|
* Note: One of the advantages of using separate processes |
116 |
|
* is that it gives the calling program some immunity from |
117 |
|
* fatal rendering errors. As discussed in raycalls.c, |
118 |
|
* Radiance tends to throw up its hands and exit at the |
119 |
|
* first sign of trouble, calling quit() to return control |
120 |
< |
* to the system. Although you can avoid exit() with |
120 |
> |
* to the top level. Although you can avoid exit() with |
121 |
|
* your own longjmp() in quit(), the cleanup afterwards |
122 |
|
* is always suspect. Through the use of subprocesses, |
123 |
|
* we avoid this pitfall by closing the processes and |
126 |
|
* of these calls, you can assume that the processes have |
127 |
|
* been cleaned up with a call to ray_close(), though you |
128 |
|
* will have to call ray_pdone() yourself if you want to |
129 |
< |
* free memory. Obviously, you cannot continue rendering, |
130 |
< |
* but otherwise your process should not be compromised. |
129 |
> |
* free memory. Obviously, you cannot continue rendering |
130 |
> |
* without risking further errors, but otherwise your |
131 |
> |
* process should not be compromised. |
132 |
|
*/ |
133 |
|
|
127 |
– |
#include <stdio.h> |
128 |
– |
#include <sys/types.h> |
129 |
– |
#include <sys/wait.h> /* XXX platform */ |
130 |
– |
|
134 |
|
#include "rtprocess.h" |
135 |
|
#include "ray.h" |
136 |
|
#include "ambient.h" |
137 |
+ |
#include <sys/types.h> |
138 |
+ |
#include <sys/wait.h> |
139 |
|
#include "selcall.h" |
140 |
|
|
141 |
|
#ifndef RAYQLEN |
142 |
< |
#define RAYQLEN 16 /* # rays to send at once */ |
142 |
> |
#define RAYQLEN 12 /* # rays to send at once */ |
143 |
|
#endif |
144 |
|
|
145 |
|
#ifndef MAX_RPROCS |
171 |
|
#define sendq_full() (r_send_next >= RAYQLEN) |
172 |
|
|
173 |
|
static int ray_pflush(void); |
174 |
< |
static void ray_pchild(int fd_in, int fd_out); |
174 |
> |
static void ray_pchild(int fd_in, int fd_out); |
175 |
|
|
176 |
|
|
177 |
|
extern void |
244 |
|
if (sendq_full() && ray_pflush() <= 0) |
245 |
|
error(INTERNAL, "ray_pflush failed in ray_psend"); |
246 |
|
|
247 |
< |
r_queue[r_send_next] = *r; |
243 |
< |
r_send_next++; |
247 |
> |
r_queue[r_send_next++] = *r; |
248 |
|
} |
249 |
|
|
250 |
|
|
257 |
|
return(0); |
258 |
|
/* check for full send queue */ |
259 |
|
if (sendq_full()) { |
260 |
< |
RAY mySend; |
257 |
< |
int rval; |
258 |
< |
mySend = *r; |
260 |
> |
RAY mySend = *r; |
261 |
|
/* wait for a result */ |
262 |
< |
rval = ray_presult(r, 0); |
262 |
> |
if (ray_presult(r, 0) <= 0) |
263 |
> |
return(-1); |
264 |
|
/* put new ray in queue */ |
265 |
< |
r_queue[r_send_next] = mySend; |
266 |
< |
r_send_next++; |
267 |
< |
return(rval); /* done */ |
265 |
> |
r_queue[r_send_next++] = mySend; |
266 |
> |
/* XXX r_send_next may now be > RAYQLEN */ |
267 |
> |
return(1); |
268 |
|
} |
269 |
< |
/* add ray to send queue */ |
270 |
< |
r_queue[r_send_next] = *r; |
268 |
< |
r_send_next++; |
269 |
> |
/* else add ray to send queue */ |
270 |
> |
r_queue[r_send_next++] = *r; |
271 |
|
/* check for returned ray... */ |
272 |
|
if (r_recv_first >= r_recv_next) |
273 |
|
return(0); |
274 |
|
/* ...one is sitting in queue */ |
275 |
< |
*r = r_queue[r_recv_first]; |
274 |
< |
r_recv_first++; |
275 |
> |
*r = r_queue[r_recv_first++]; |
276 |
|
return(1); |
277 |
|
} |
278 |
|
|
292 |
|
return(0); |
293 |
|
/* check queued results first */ |
294 |
|
if (r_recv_first < r_recv_next) { |
295 |
< |
*r = r_queue[r_recv_first]; |
295 |
< |
r_recv_first++; |
295 |
> |
*r = r_queue[r_recv_first++]; |
296 |
|
return(1); |
297 |
|
} |
298 |
|
n = ray_pnprocs - ray_pnidle; /* pending before flush? */ |
306 |
|
n = ray_pnprocs - ray_pnidle; |
307 |
|
if (n <= 0) /* return if nothing to await */ |
308 |
|
return(0); |
309 |
+ |
if (!poll && ray_pnprocs == 1) /* one process -> skip select() */ |
310 |
+ |
FD_SET(r_proc[0].fd_recv, &readset); |
311 |
+ |
|
312 |
|
getready: /* any children waiting for us? */ |
313 |
|
for (pn = ray_pnprocs; pn--; ) |
314 |
|
if (FD_ISSET(r_proc[pn].fd_recv, &readset) || |
369 |
|
rp->slights = NULL; |
370 |
|
} |
371 |
|
/* return first ray received */ |
372 |
< |
*r = r_queue[r_recv_first]; |
370 |
< |
r_recv_first++; |
372 |
> |
*r = r_queue[r_recv_first++]; |
373 |
|
return(1); |
374 |
|
} |
375 |
|
|
397 |
|
{ |
398 |
|
int n; |
399 |
|
register int i; |
400 |
+ |
/* flag child process for quit() */ |
401 |
+ |
ray_pnprocs = -1; |
402 |
|
/* read each ray request set */ |
403 |
|
while ((n = read(fd_in, (char *)r_queue, sizeof(r_queue))) > 0) { |
404 |
|
int n2; |
405 |
< |
if (n % sizeof(RAY)) |
405 |
> |
if (n < sizeof(RAY)) |
406 |
|
break; |
403 |
– |
n /= sizeof(RAY); |
407 |
|
/* get smuggled set length */ |
408 |
< |
n2 = r_queue[0].crtype - n; |
408 |
> |
n2 = sizeof(RAY)*r_queue[0].crtype - n; |
409 |
|
if (n2 < 0) |
410 |
|
error(INTERNAL, "buffer over-read in ray_pchild"); |
411 |
|
if (n2 > 0) { /* read the rest of the set */ |
412 |
< |
i = readbuf(fd_in, (char *)(r_queue+n), |
413 |
< |
sizeof(RAY)*n2); |
411 |
< |
if (i != sizeof(RAY)*n2) |
412 |
> |
i = readbuf(fd_in, (char *)r_queue + n, n2); |
413 |
> |
if (i != n2) |
414 |
|
break; |
415 |
|
n += n2; |
416 |
|
} |
417 |
+ |
n /= sizeof(RAY); |
418 |
|
/* evaluate rays */ |
419 |
|
for (i = 0; i < n; i++) { |
420 |
|
r_queue[i].crtype = r_queue[i].rtype; |
421 |
|
r_queue[i].parent = NULL; |
422 |
|
r_queue[i].clipset = NULL; |
423 |
|
r_queue[i].slights = NULL; |
421 |
– |
r_queue[i].revf = raytrace; |
424 |
|
samplendx++; |
425 |
|
rayclear(&r_queue[i]); |
426 |
|
rayvalue(&r_queue[i]); |
447 |
|
nadd = MAX_NPROCS - ray_pnprocs; |
448 |
|
if (nadd <= 0) |
449 |
|
return; |
450 |
< |
fflush(stderr); /* clear pending output */ |
451 |
< |
fflush(stdout); |
450 |
> |
ambsync(); /* load any new ambient values */ |
451 |
> |
fflush(NULL); /* clear pending output */ |
452 |
|
while (nadd--) { /* fork each new process */ |
453 |
|
int p0[2], p1[2]; |
454 |
|
if (pipe(p0) < 0 || pipe(p1) < 0) |
466 |
|
if (r_proc[ray_pnprocs].pid < 0) |
467 |
|
error(SYSTEM, "cannot fork child process"); |
468 |
|
close(p1[0]); close(p0[1]); |
469 |
+ |
/* |
470 |
+ |
* Close write stream on exec to avoid multiprocessing deadlock. |
471 |
+ |
* No use in read stream without it, so set flag there as well. |
472 |
+ |
*/ |
473 |
+ |
fcntl(p1[1], F_SETFD, FD_CLOEXEC); |
474 |
+ |
fcntl(p0[0], F_SETFD, FD_CLOEXEC); |
475 |
|
r_proc[ray_pnprocs].fd_send = p1[1]; |
476 |
|
r_proc[ray_pnprocs].fd_recv = p0[0]; |
477 |
|
r_proc[ray_pnprocs].npending = 0; |
504 |
|
ray_pnprocs--; |
505 |
|
close(r_proc[ray_pnprocs].fd_recv); |
506 |
|
close(r_proc[ray_pnprocs].fd_send); |
507 |
< |
while (wait(&status) != r_proc[ray_pnprocs].pid) |
508 |
< |
; |
507 |
> |
if (waitpid(r_proc[ray_pnprocs].pid, &status, 0) < 0) |
508 |
> |
status = 127<<8; |
509 |
|
if (status) { |
510 |
|
sprintf(errmsg, |
511 |
|
"rendering process %d exited with code %d", |
522 |
|
quit(ec) /* make sure exit is called */ |
523 |
|
int ec; |
524 |
|
{ |
525 |
+ |
if (ray_pnprocs > 0) /* close children if any */ |
526 |
+ |
ray_pclose(0); |
527 |
|
exit(ec); |
528 |
|
} |